Self-evolvable logic fabric

ABSTRACT

Methods and systems for achieving self-organized growth of a logic pathway. A number of hardware modules that represents a core can be configured and communicated via a packet routing architecture. Each core includes a plurality of sub-modules that interact dynamically to a growth algorithm. A flow network can be created between a sensor input and a prediction of a desired sensor input and a link can be formed between a regularity within a core and another core via a link-flow-selection process. A digital data packet can be transmitted between the cores for communicating activation of the regularity and to exchange energy. Such physically-self organized circuit fabric system interacts dynamically to a growth algorithm that takes the input to produce a desired output and continuously self-repair and/or heal if damaged.

CROSS-REFERENCE TO PROVISIONAL APPLICATION

This application claims priority under 35 U.S.C. 119(e) to U.S.Provisional Patent Application Ser. No. 61/616,468, entitled “SelfEvolvable Logic Fabric,” which was filed on Mar. 28, 2012, thedisclosure of which is incorporated herein by reference in its entirety.

TECHNICAL FIELD

Embodiments are generally related to self-evolvable control systems andmethods. Embodiments are also related to self-organizing circuits.Embodiments are additionally related to attractor-based systems.

BACKGROUND OF THE INVENTION

A number of technological and economic barriers currently exist in thedevelopment of new types of electronic devices and systems. As devicesapproach the atomic scale, they become noisy and prone to faults inproduction and use. Opposite to the consumer trend of price reduction,the cost for producers to fulfill Moore's law is increasingdramatically. At the same time, however, it is also becomingincreasingly clear that current computing approaches will not meet thechallenges brought by adaptive autonomous controllers. Thepower-discrepancy between a biological solution and an advancedcomputing system is so large that it points to flaws in notions ofcomputing.

FIG. 1 illustrates a graph 100 depicting power-discrepancy betweenbiological solutions and advanced computing systems, in accordance withthe disclosed embodiments. For example, consider a human body simulatedat a moderate fidelity such that each cell of the body is allocated toone CPU and that the distance between a memory and a processor isdistance d. At an operating voltage V=1 and d=1 cm, the simulation wouldconsume at minimum 100 GW of power, or about the total peak powerconsumption of France in 2011. If the voltage is lowered to athermodynamic limit of V=0.025V (kT at room temperature) and theCPU-memory distance to the diameter of an average cell, d=10⁻⁵ m, itwill still consume 62.5 kW, which is 625 times as much energy as isactually consumed by the human body. The distance between the CPU andmemory must be at least 2 nm or less for the simulation to equal theefficiency of biology if the operating voltage is set to 70 mV, theresting potential of a neuron. The progromatic paradigm breaks down atsuch low voltages since the barrier energy between bit states becomescomparable to the thermal energy. For these reason, it's relativelyclear that a new type of computing system based on self-organization ofnature must be created. While some point to quantum computing as apotential solution, it must be noted that the extreme isolationsrequired to maintain a qubit in its superposition state are at odds withthe solution which has clearly been found by life, which is heavilyintegrated with its environment and operates in extremely volatileconditions. What is needed is a solution based more on theself-repairing and self-assembling properties of life while stillintegrating with modern electronics.

Nature is capable of building structures of far greater complexity thanany modern chip and it is capable of doing it while embedded in the realworld. If the principles of autonomous self-organization areilluminated, it can cascade through all parts of world economy. Selforganizing circuits can dramatically reduce the cost of fabrication byincreasing yields as the circuits can adapt around faults. Anyapplication that must interact with a complex changing environment is apotential platform for the self-organizing autonomous control circuitry.The ability to heal, a natural consequence of an attractor-basedself-organization, leads to enhanced survival in hostile environments.

Based on the foregoing, it is believed that a need exists for animproved system and method for achieving self organized growth of alogic and/or algorithmic pathways. A need also exists for an improvedphysically-self-organized circuit fabric system that interactsdynamically to growth algorithms and continuously self-repairs ifdamaged, as described in greater detail herein.

BRIEF SUMMARY

The following summary is provided to facilitate an understanding of someof the innovative features unique to the disclosed embodiments and isnot intended to be a full description. A full appreciation of thevarious aspects of the embodiments disclosed herein can be gained bytaking the entire specification, claims, drawings, and abstract as awhole.

It is, therefore, one aspect of the disclosed embodiments to provide foran improved self-evolvable control system and method.

It is another aspect of the disclosed embodiments to provide for animproved system and method for achieving self-organized growth of logicpathways.

It is yet another aspect of the disclosed embodiments to provide for animproved self evolvable logic fabric system that is capable of selfrepair and/or heal if damaged.

The aforementioned aspects and other objectives and advantages can nowbe achieved as described herein. A system and method for achievingself-organized growth of logic pathways is disclosed herein. A number ofhardware modules that represent a core can be configured and communicatevia a packet routing architecture. Each core includes a number ofsub-modules that interact dynamically to growth algorithms. A flownetwork can be created between inputs via a link-flow-selection process.A digital data packet can be transmitted between the cores forcommunicating activation of the regularity and to exchange energytokens. Such physically self-organized circuit fabric system interactsdynamically to grow algorithms that maximize the flow of its energytoken.

An input packet can be received via an input packet receive module.Packets may be transmitted directly to an input packet return module ordropped. From the input packet receive module, packets are mapped to acontent addressable memory module (CAM). The function of the CAM is toassign the source packets address with one of a limited number of inputlines. This may be accomplished with CAM's least-recently used caches,least-frequency used caches, or other methods which differ in theirstrategy in allocated lines to new input address should the line addressspace fill up. Thus, a sender's address can be mapped to a dedicatedinput line on a pattern register and a bit matching can be performedbetween the sender's address and an internally stored bit pattern. Inaddition to the methods listed above, an existing entry can beoverwritten such that a least-energy-dissipating link is over-writtenfirst when a new input address is present. This is determined by theflow of the energy token through the network, as will be discussed.

The pattern can be presented to a regularity detector once all inputpackets arrive. A regularity ID from the regularity detector can berepresented as a bit pattern and the regularity ID can be transmitted asinput to a thermodynamic random access memory (kRAM). The function ofthe kRAM is to store information related to the regularities energy andits link structure and link weights to other cores. Each link representsan address to another core within the network. A link address from thekRAM can be transmitted to an output packet send module to generate andtransmit the packet to an address specified in the kRAM. The addressspecified by the kRAM may be programmed by a user or else evolvethermodynamically. If set to evolve thermodynamically, the stability ofthe bit patterns is given by the total energy tokens flowing through thelink. The total energy allocated to each address in the kRAM is given bythe kRAM's link weights. As more of the energy token flows through thelink, it becomes stronger. Thus, one can view a kRAM as aself-organizing routing module that is attempting to maximize the totalflow of energy tokens.

An output packet return module that includes information regarding theenergy accepted from the down-stream regularity can receive a returnpacket. The information can then be provided to the kRAM in order toapply feedback in proportion to an amount of energy that is dissipatedthough the respective link. The regularities energy can be communicatedto an input packet return module in order to calculate energy theregularity is capable of sinking for each active input regularity andcommunicate the energy via a return packet. The kRAM module comprises acollection of thermodynamic bits, which change state with an increasedprobability in the absence of an externally applied feedback signal andstabilize in the presence of a feedback signal. The feedback signal isgenerated when the energy tokens are dissipated (i.e. accepted) througha link. That is, when a packet is sent to the address specified in thekRAM module it contains some amount of energy. If this energy isaccepted, a return packet is sent specifying how much energy wasaccepted (dissipated). The feedback is thus proportionally to thedissipated or accepted energy.

The energy can be represented as a digital and/or analog signal and theenergy can be accounted via a symbolic mechanism of an arithmeticoperator. The energy can be represented in a pulse timing manner so thata pulse that arrives first possess more energy and the pulse thatarrives later possess less energy, relative to some global phase orclock signal. The energy can be deleted from the network when desiredevents occur. A negative energy value can suffice as a sink if theenergy is represented as a symbolic number. Such a technique may thus beused to direct energy sinks to specific cores or regularities withincores. In this manner, each core is attempting to recognize theregularities present on its inputs while evolving links to maximize thedissipation of energy. The resulting network of regularities linked byenergy flow thus represents an algorithm or logic path that convertinputs into desired outputs.

A number of embodiments, preferred and alternative, are disclosedherein. For example, in one embodiment, a method for the self-organizedgrowth of at least one logic pathway can be implemented. Such a methodmay include, for example, the steps or logical operations ofcommunicating a plurality of cores via a packet routing architecture,wherein at least one core includes sub-modules that interact dynamicallywith one another forming a link between a regularity within the at leastone core and at least one other core via a link-flow-selection process,and transmitting a digital data packet between the at least one core andthe at least one other core to communicate an activation of theregularity and to exchange energy to thereby grow the at least one logicpathway in a self-organized manner. In another embodiment, the pluralityof hardware cores can represent the at least one core. In anotherembodiment, the sub-modules can interact to evolve the logic pathway. Instill another embodiment, a step or logical operation can be implementedfor creating a flow network between a sensor input and a sink event. Inyet another embodiment, the sink event can constitute a prediction ofthe sensor input.

In another embodiment, steps of logical operations can be implementedfor receiving at least one input packet via an input packet receivemodule; transmitting the at least one packet to a thermodynamic contentaddressable memory module; mapping a sender address to a dedicated inputline on a pattern register; performing a bit-matching between the senderaddress and an internally stored bit pattern; and overwriting anexisting entry such that a least-energy-dissipating link is over-writtenfirst when a new input address is present.

In yet another embodiment, steps or logical operations can beimplemented for presenting the internally stored bit patter to aregularity detector once all input packets are arrived; representing aregularity ID from the regularity detector as a bit pattern; andtransmitting the regularity ID as an input to a thermodynamic randomaccess memory in order to retrieve information related to the regularityenergy and links, wherein each link represent an address to the at leastone other core within the network.

In still another embodiment, steps or logical operations can beimplemented for sending a link address and energy from the thermodynamicrandom access memory to an output packet send module; generating andtransmitting the packet to a core address specified in the thermodynamicrandom access memory; receiving a return packet by an output packetreturn module that includes information regarding the energy acceptedfrom the regularity; providing the information to the thermodynamicrandom access memory in order to apply feedback in proportion to anamount of energy that is accepted by receiving core; communicating theregularity energy to an input packet return module in order to calculatean amount of energy that the regularity is capable of sinking for eachactive input regularity; and communicating the energy via a returnpacket.

In another embodiment the thermodynamic random access memory can includecore addresses and a regularity energy level. In other embodiments, thethermodynamic random access memory can include a plurality ofthermodynamic bits which flip state randomly with an increasedprobability in absence of an externally applied feedback signal andwhich stabilize in presence of the feedback signal.

In yet another embodiment, a hardware structure can be configured, whichincludes multiple cores, wherein each core among the multiple corescomprises functionalities of regularity extraction andlink-flow-selection between regularities, wherein a function of thehardware structure is to evolve energy-dissipating pathways between theregularities. In another embodiment, such energy can be represented as adigital token or a number. In other embodiments, the aforementionedlink-flow-selection can be provided by: linking a sending regularitywith at least one receiving regularity with variable-strength links,each link comprising a link address and a strength; and allocatingenergy from the sending regularity to the at least one receivingregularity in proportion to link strengths.

In other embodiments, the link address can be represented as volatilebits such that an absence of energetic feedback causes the volatile bitsto reconfigure a state and an application of the energetic feedbackreduces a probability of state reconfiguration. In some embodiments, theenergy accepted by a receiving regularity can be associated with astabilizing feedback to volatile links of the sending regularity.

In another embodiment, a system for the self-organized growth of atleast one logic pathway can be implemented. Such system can include, forexample, a plurality of cores capable of being communicated via a packetrouting architecture, wherein at least one core includes sub-modulesthat interact dynamically with one another; a link formed between aregularity within the at least one core and at least one other core viaa link-flow-selection process; and transmission means for transmitting adigital data packet between the at least one core and the at least oneother core to communicate an activation of the regularity and toexchange energy to thereby grow the at least one logic pathway in aself-organized manner. In some embodiments, the plurality of hardwarecores is capable of representing the at least one core. In otherembodiments, the sub-modules can interact to evolve a logic pathway. Inyet other embodiments, such a system can further include a flow networkcreated between a sensor input and a sink event. In still otherembodiments, the sink event can comprise a prediction of the sensorinput.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying figures, in which like reference numerals refer toidentical or functionally-similar elements throughout the separate viewsand which are incorporated in and form a part of the specification,further illustrate the present invention and, together with the detaileddescription of the invention, serve to explain the principles of thepresent invention.

FIG. 1 illustrates a graph depicting power-discrepancy between abiological solution and an advanced computing system, in accordance withthe disclosed embodiments;

FIG. 2 illustrates a block diagram of a self-evolvable logic fabriccore, in accordance with the disclosed embodiments;

FIG. 3 illustrates a schematic view of a logic function composed of twocomponents, in accordance with the disclosed embodiments;

FIG. 4 illustrates a schematic view of logic functions represented asfinite-state-machines, where a first state recognizes a condition andthe transitions to a new state represent a logic function, in accordancewith the disclosed embodiments;

FIG. 5 illustrates a schematic view of a regularity detector thatconverts an input pattern to a regularity ID, in accordance with thedisclosed embodiments;

FIG. 6 illustrates a schematic view of a network of cores that linksregularities within cores to other cores, in accordance with thedisclosed embodiments; and

FIG. 7 illustrates a high level flow chart of operations illustratinglogical operational steps of a core for achieving self-organized growthof a logic pathways within a network of cores, in accordance with thedisclosed embodiments.

DETAILED DESCRIPTION

The particular values and configurations discussed in these non-limitingexamples can be varied and are cited merely to illustrate at least oneembodiment and are not intended to limit the scope thereof.

The embodiments will now be described more fully hereinafter withreference to the accompanying drawings, in which illustrativeembodiments of the invention are shown. The embodiments disclosed hereincan be embodied in many different forms and should not be construed aslimited to the embodiments set forth herein; rather, these embodimentsare provided so that this disclosure will be thorough and complete, andwill fully convey the scope of the invention to those skilled in theart. Like numbers refer to like elements throughout. As used herein, theterm “and/or” includes any and all combinations of one or more of theassociated listed items.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the invention. Asused herein, the singular forms “a”, “an” and “the” are intended toinclude the plural forms as well, unless the context clearly indicatesotherwise. It will be further understood that the terms “comprises”and/or “comprising,” when used in this specification, specify thepresence of stated features, integers, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, integers, steps, operations, elements,components, and/or groups thereof.

As will be appreciated by one skilled in the art, the present inventioncan be embodied as a method, data processing system, or computer programproduct. Accordingly, the present invention may take the form of anentire hardware embodiment, an entire software embodiment or anembodiment combining software and hardware aspects all generallyreferred to herein as a “circuit” or “module.” Furthermore, the presentinvention may take the form of a computer program product on acomputer-usable storage medium having computer-usable program codeembodied in the medium.

FIG. 2 illustrates a block diagram of a self-evolvable logic fabricsystem core 200, in accordance with the disclosed embodiments. The core200 interacts dynamically with other cores to grow algorithms. The core200 can be configured to include a number of hardware modules such as,for example, an input packet receive module 215, an input packet returnmodule 225, an output packet send module 255, and an output packetreturn module 260. The self-evolvable logic fabric system composed ofmany instances of core 200 further includes a thermodynamic contentaddressable memory (kCAM) module 220, a pattern register 230, aregularity detector 235, and a thermodynamic random access memory (kRAM)module 240.

The input packet receive module 215 receives an input packet andtransmits each packet to the thermodynamic content addressable memorymodule 220. In some cases it may send the packet directly to the inputpacket return module, for example, if the packet is rejected.Content-addressable memory (CAM) is a special type of computer memoryemployed in certain very high speed searching applications. In this use,its function is to map the input packets source address to input lines.This function may also be accomplished with other methods, for example,a Least-Recently-Used Cache, Least-Frequently-Used-Cache, etc. In eachcase, the relevant difference concerns which address space isover-written when maximum capacity is reached. One strategy forover-writing memory may be based on the total energy token dissipationor flow occurring over the link such that high-flow links are kept andlow-flow connections are over-written. The pattern register 230functions to serialize the active inputs arriving from the kCAM suchthat a parallel pattern may be presented to the regularity detector 235.

The regularity detector 235 receives the input pattern from the patternregister. The regularity detector 235 generates a regularity ID that canbe represented as a bit pattern and transmits the regularity ID as inputto the thermodynamic random access memory module 240, which storesinformation related to the regularities energy 245 and its links 250.Links 250 represents addresses to other cores within the network as wellas the total energy to allocate in each direction. One can thus see alink as a bit vector such that the state of the bits encode the addressand the magnitude of the bit-vector encodes the relative energy toallocate to the links address, relative to the other links. Alternately,the links address may be programmed or set by the user of the system andthe link weights evolve. Should the total energy in a regularity levelfall below some threshold, packet propagation is terminated.

The output packet send module 255 can receive a link address and energytoken value from the kRAM module 240 to generate and transmit the packetto the address specified. The output packet return module 260 receives areturn packet that includes information regarding the energy 245accepted from the regularity. The information can then be provided tothe thermodynamic random access memory (kRAM) module 240 in order toapply feedback in proportion to an amount of energy 245 that isdissipated.

kT-RAM is a memory architecture that may be composed of thermodynamicbits. A thermodynamic bit is a bit with a variable mutation rate thatcan be set by applied feedback. As more feedback is applied, theprobability that the bit can flip states in a unit of time goes to zero.Thus, the kRAM 240 is a constantly mutating access memory if thefeedback is withheld from all bits. In the case where feedback isprovided to all bits, it becomes a traditional ROM. A significantdifference between kRAM 240 and normal RAM is that kRAM 240 is notwritten by a user but rather configures its own state through randomthermal fluctuations and is later stabilized by feedback. That is,absent feedback a thermodynamic bit will randomly flip states untilfeedback arrives.

The kRAM 240 can be constructed of arrays of AHaH nodes, which encodethe bit state on a differential pair of memristive devices. The kRAM 240includes a collection of thermodynamic bits which flip their staterandomly with an increased probability in the absence of an externallyapplied feedback signal and which stabilize in the presence of thefeedback signal. This can be accomplished through many mechanisms. Theexternal feedback signal for each link 250 within the kRAM 240represents the energy that the link is responsible for dissipating. Asthe link routes packets to destinations that accept its energy, it willreceive more feedback and stabilize. The input packet return module 225receives the regularities energy 245 to in order to calculate the energy245 the regularity is capable of sinking for each active inputregularity and communicate the energy 245 via a return packet.

In an alternate embodiment, the kRAM may act to evolve the link weightswhile the link address are programmed by a user. In this embodiment,each link maintains a weight that governs how much energy is allocatedto each destination address, relative to other links. In this manner,the general link topology of the core network is specified by the userof the system, while a sub-network is selected by the kRAM so as tomaximize the energy flow within the network.

FIG. 3 illustrates a schematic view of a logic function 300 composed oftwo components 365 and 370, in accordance with the disclosedembodiments. Modern computing is based on the concept of intrinsiclogic, which is to say that the logic function of a circuit is intrinsicto the circuit itself. By connecting transistors or other electronicelements in certain configurations, logic functions of any type can beformed. Intrinsic logic is defined not by the circuit, but rather by thestructure of the information that the circuit is processing. Logicfunctions are attractor states of a feedback circuit operating oninternal modifiable weights and governed by the structure of theinformation being processed. For example, consider the NAND logic gaterepresented as a lookup-table, as shown in FIG. 3. Two inputs A and Bproduce an output Y. The logic function 300 first recognizes thecondition 365 and the logic gate will produce an output 370 for a givencondition. This intrinsic assumption of condition is at the core ofmodern digital logic, but it is fundamentally at odds withself-organizing logic structures operating on natural data streams. Onemajor problem with extrinsic logic is dimensionality. Although manyinputs may be present, the actual information content is much lower thanthe maximal carrying capacity. That is to say, there are many lessconditions than what could theoretically be carried over the wires orinputs.

Extrinsic attractors are most suitable for information-processingsystems. An example of the extrinsic attractor is the brain. Thestructure of the brain is a reflection of the structure of theinformation it is processing, as evidence by the fact that ones decisionare based on prior experiences or memories. Another example of anextrinsic attractor is a fast-flowing river. The structure of the rapidscan be created from the water flowing over the streambed. Countlessmolecules of water come and go, but the structure of the rapids remainthe same. Without the underlying structure of the stream-bed or theenergy dissipation brought on by the gravitational gradient, thestructure will quickly dissipate. Three ingredients are necessary forthe extrinsic attractor. First, energy must be dissipated. In the river,this can be provided by a gravitational gradient. Second, the water mustinteract with itself and the environment (the stream bed) according to aplasticity rule. In the river, the inter-molecular forces of water canprovide this. Third, there must be external structure, for example, therocks and boulders of the streambed. In the case of extrinsic logic, theexternal structure is that of the information, the energy source is theelectric potential, and the interaction rule is the AHaH rule.

FIG. 4 illustrates a schematic view of logic functions 400 representedas finite-state-machines, where a first state 410, 430, and 450recognizes a condition and transitions to a new state 420, 440, and 460.This two-phase process represents a logic function, in accordance withthe disclosed embodiments. A logic function can be broken into twocomponents related to the detection of condition and the output ofstate. The NAND, OR, XOR or any other logic functions can be representedas finite-state-machines (FSM) with three states, as shown in FIG. 4.The first state 410, 430, and 450 determines the condition of theinputs. Depending on the condition, the machine transitions to newstates 420, 440, and 460 representing the output. Note that the logicfunction can be obtained through a link structure in the FSM and thatthe first state, the condition recognition, is the same for all. Statedanother way, the recognition of a condition is the recognition of a dataregularity.

FIG. 5 illustrates a schematic view of a regularity extraction module500 that converts an input pattern 510 to regularity ID 520, inaccordance with the disclosed embodiments. The system 200 evolves thelink structure 250 that links regularities 530 to cores 600, as seen inFIG. 6. The links 250 can be evolved through a process oflink-flow-selection. FIG. 6 illustrates a schematic view of a corenetwork 600 that links the regularities 530 within the cores to othercores, in accordance with the disclosed embodiments. The logic functionscan are represented as finite-state-machine in which one state acts asthe regularity detector 235 and the links 250 to other states representthe logic output. Collectives of AHAH (Anti-Hebbian and Hebbian) nodemay act as the regularity detectors 235 detailed in other disclosures.The link 250 can be first randomly created between the regularity 530within a core and another core. Should the regularity 530 be activewithin the core 500, energy 245 can be transferred between theregularity 530 and the regularity of the receiving core 500. Whendesired events occur, energy may be sunk. Since link structure isstabilized via energy flow (i.e., link-flow selection), the network ofregularities which emerges represents an evolved logic pathway oralgorithm.

In general, Hebbian theory is a scientific theory in biologicalneuroscience which explains the adaptation of neurons in the brainduring the learning process. It describes a basic mechanism for synapticplasticity wherein an increase in synaptic efficacy arises from thepresynaptic cells repeated and persistent stimulation of thepostsynaptic cell. In neuroethology and the study of learning,anti-Hebbian learning describes a particular class of learning rule bywhich synaptic plasticity can be controlled. These rules are based on areversal of Hebb's postulate and therefore can be simplisticallyunderstood as dictating reduction of the strength of synapticconnectivity between neurons following a scenario in which a neurondirectly contributes to production of an action potential in anotherneuron.

The energy flow network 600 can be built of numerous connections, forexample, a top-down process 610, a feed forward process 620, and alateral process 640. Sensory inputs 630 may be energy sources anddesired outputs may be sinks, or visa versa. It is required that theuser specify energy sources and sinks such that network structure mayemerge. It can be appreciated that although the network 600 may possesssome set capacity in the amount of energy it can store within its nodes,the only way the network 600 can achieve constant flow of energy fromthe sources to sinks is to evolve algorithmic structure necessary tosink the energy.

FIG. 7 illustrates a high level flow chart of operation illustratinglogical operational steps of a method 700 for achieving self-organizedgrowth of a logic pathway, in accordance with the disclosed embodiments.Initially, input packets can be received via, for example, the inputpacket receive module 215 discussed earlier, and each packet can betransmitted to, for example, the thermodynamic content addressablememory (kCAM) module 220, as indicated at block 710. Next, as describedat block 720, the thermodynamic content addressable memory module 220can map the sender's address to a dedicated input line on the patternregister 230. Existing maping between senders address and input linescan be overwritten in a number of ways as depicted at block 730, forexample, least frequently used, last-used or least energy dissipating.

Once all input packets for a set time period or clock have arrived andthe thermodynamic content addressable memory module 220 has translatedthem to input lines on the pattern register 230, the pattern can bepresented to the regularity detector 235, as illustrated at block 740.The output of the regularity detector 235 can constitute a regularity IDwhich can be represented, for example, as a bit pattern. The regularityID can be input to the thermodynamic random access memory module 240,which serves to store information related to the regularities energy 245and links 250. As indicated next at block 750, an operation can beimplemented for looking up regularity or regularities' links in thekRAM.

The thermodynamic random access memory module 240 outputs the linkaddress and regularity energy to the output packet send module 255 togenerate and transmit packets to the addresses specified in thethermodynamic random access memory module 240, as depicted at block 760.The return packets can be received in the output packet return module260 that includes information regarding how much energy is accepted andfrom what regularity. This information can be provided to thethermodynamic random access memory module 240, which applies feedback inproportion to the amount of energy that was accepted, as depicted atblock 770.

The energy 245 can be communicated to the input packet return module225, which calculates how much energy the regularity is capable ofsinking for each active input regularity and communicates this through areturn packet to facilitate the same feedback to the regularities thatproject to the core, as shown at block 780. The system 200 constructs anetwork of regularities through the operation of the cores 200 on inputpatterns 510. The flow network 600 can be created between the sensorinputs 630 and desired sink events. Should sink event occur, the energy245 can be deleted or otherwise removed from the network. If energy 245is represented as symbolic numbers, negative energy values can sufficeas a sink.

Based on the foregoing, it can be appreciated that a number ofembodiments, preferred or alternative, are disclosed herein. Forexample, in one embodiment, a method for the self-organized growth of atleast one logic pathway can be implemented. Such a method may include,for example, the steps or logical operations of communicating aplurality of cores via a packet routing architecture, wherein at leastone core includes sub-modules that interact dynamically with oneanother, forming a link between a regularity within the at least onecore and at least one other core via a link-flow-selection process, andtransmitting a digital data packet between the at least one core and theat least one other core to communicate an activation of the regularityand to exchange energy to thereby grow the at least one logic pathway ina self-organized manner. In another embodiment, the plurality ofhardware cores can represent the at least one core. In anotherembodiment, the sub-modules can interact to evolve the logic pathway. Instill another embodiment, a step or logical operation can be implementedfor creating a flow network between a sensor input and a sink event. Inyet another embodiment, the sink event can constitute a prediction ofthe sensor input.

In another embodiment, steps of logical operations can be implementedfor receiving at least one input packet via an input packet receivemodule; transmitting the at least one packet to a thermodynamic contentaddressable memory module; mapping a sender address to a dedicated inputline on a pattern register; performing a bit-matching between the senderaddress and an internally stored bit pattern; and overwriting anexisting entry such that a least-energy-dissipating link is over-writtenfirst when a new input address is present.

In yet another embodiment, steps or logical operations can beimplemented for presenting the internally stored bit pattern to aregularity detector once all input packets are arrived; representing aregularity ID from the regularity detector as a bit pattern; andtransmitting the regularity ID as an input to a thermodynamic randomaccess memory in order to retrieve information related to the regularityenergy and links, wherein each link represent an address to the at leastone other core within the network.

In still another embodiment, steps or logical operations can beimplemented for sending a link address and energy from the thermodynamicrandom access memory to an output packet send module; generating andtransmitting the packet to a core address specified in the thermodynamicrandom access memory; receiving a return packet by an output packetreturn module that includes information regarding the energy acceptedfrom the regularity; providing the information to the thermodynamicrandom access memory in order to apply feedback in proportion to anamount of energy that is accepted by reviewing core; communicating theregularity energy to an input packet return module in order to calculatean amount of energy that the regularity is capable of sinking for eachactive input regularity; and communicating the energy via a returnpacket.

In another embodiment the thermodynamic random access memory can includecore addresses and a regularity energy level. In other embodiments, thethermodynamic random access memory can include a plurality ofthermodynamic bits which flip state randomly with an increasedprobability in absence of an externally applied feedback signal andwhich stabilize in presence of the feedback signal.

In yet another embodiment, a hardware structure can be configured, whichincludes multiple cores, wherein each core among the multiple corescomprises functionalities of regularity extraction andlink-flow-selection between regularities, wherein a function of thehardware structure is to evolve energy-dissipating pathways between theregularities. In another embodiment, such energy can be represented as adigital token or a number. In other embodiments, the aforementionedlink-flow-selection can be provided by: linking a sending regularitywith at least one receiving regularity with variable-strength links,each link comprising a link address and a strength; and allocatingenergy from the sending regularity to the at least one receivingregularity in proportion to link strengths.

In other embodiments, the link address can be represented as volatilebits such that an absence of energetic feedback causes the volatile bitsto reconfigure a state and an application of the energetic feedbackreduces a probability of state reconfiguration. In some embodiments, theenergy accepted by a receiving regularity can be associated with astabilizing feedback to volatile links of the sending regularity.

In another embodiment, a system for the self-organized growth of atleast one logic pathway can be implemented. Such system can include, forexample, a plurality of cores capable of being communicated via a packetrouting architecture, wherein at least one core includes sub-modulesthat interact dynamically with one another; a link formed between aregularity within the at least one core and at least one other core viaa link-flow-selection process; and transmission means for transmitting adigital data packet between the at least one core and the at least oneother core to communicate an activation of the regularity and toexchange energy to thereby grow the at least one logic pathway in aself-organized manner. In some embodiments, the plurality of hardwarecores is capable of representing the at least one core. In otherembodiments, the sub-modules can interact to evolve a logic pathway. Inyet other embodiments, such a system can further include a flow networkcreated between a sensor input and a sink event. In still otherembodiments, the sink event can comprise a prediction of the sensorinput.

It will be appreciated that variations of the above-disclosed and otherfeatures and functions, or alternatives thereof, may be desirablycombined into many other different systems or applications. Also, thatvarious presently unforeseen or unanticipated alternatives,modifications, variations or improvements therein may be subsequentlymade by those skilled in the art which are also intended to beencompassed by the following claims.

The invention claimed is:
 1. A method for the self-organized growth ofat least one logic pathway, said method comprising: communicating aplurality of cores via a packet routing architecture, wherein at leastone core includes sub-modules that interact dynamically with oneanother; forming a link between a regularity within said at least onecore and at least one other core via a link-flow-selection process;transmitting a digital data packet between said at least one core andsaid at least one other core to communicate an activation of saidregularity and to exchange energy to thereby grow said at least onelogic pathway in a self-organized manner; receiving at least one inputpacket via an input packet receive module; transmitting said at leastone packet to a thermodynamic content addressable memory module; mappinga sender address to a dedicated input line on a pattern register;performing a bit-matching between said sender address and an internallystored bit pattern; and overwriting an existing entry such that aleast-enemy-dissipating link is over-written first when a new inputaddress is present.
 2. The method of claim 1 further comprisingconfiguring said plurality of hardware cores to represent said at leastone core.
 3. The method of claim 1 wherein said sub-modules interact toevolve said at least one logic pathway.
 4. The method of claim 1 furthercomprising creating a flow network between a senor input and a sinkevent.
 5. The method of claim 4 wherein said sink event comprises aprediction of said sensor input.
 6. The method of claim 4 furthercomprising: presenting said internally stored bit pattern to aregularity detector once all input packets are arrived; representing aregularity ID from said regularity detector as a bit pattern; andtransmitting said regularity ID as an input to a thermodynamic randomaccess memory, in order to retrieve information related to saidregularity energy and links, wherein each link represent an address tosaid at least one other core within said network.
 7. The method of claim6 further comprising: sending a link address and energy from saidthermodynamic random access memory to an output packet send module;generating and transmitting said packet to a core address specified insaid thermodynamic random access memory; receiving a return packet by anoutput packet return module that includes information regarding saidenergy accepted from said regularity; providing said information to saidthermodynamic random access memory in order to apply feedback inproportion to an amount of energy that is accepted by revieving core;communicating said regularity energy to an input packet return module inorder to calculate an amount of energy that said regularity is capableof sinking for each active input regularity; and communicating saidenergy via a return packet.
 8. The method of claim 1 wherein saidthermodynamic random access memory comprises core addresses andregularity energy level.
 9. The method of claim 1 wherein saidthermodynamic random access memory comprises a plurality ofthermodynamic bits which flip state randomly with an increasedprobability in absence of an externally applied feedback signal andwhich stabilize in presence of said feedback signal.
 10. A hardwarestructure, comprising: multiple cores, wherein each core among saidmultiple cores comprises functionalities of regularity extraction andlink-flow-selection between regularities, wherein a function of saidhardware structure is to evolve energy-dissipating pathways between saidregularities.
 11. The hardware structure claim of 10 wherein said energyis represented as a digital token or a number.
 12. The hardwarestructure of claim 10 wherein said link-flow-selection is provided by:linking a sending regularity with at least one receiving regularity withvariable-strength links, each link comprising a link address and astrength; and allocating energy from said sending regularity to said atleast one receiving regularity in proportion to link strengths.
 13. Thehardware structure of claim 12 wherein said link address is representedas volatile bits such that an absence of energetic feedback causes saidvolatile bits to reconfigure a state and an application of saidenergetic feedback reduces a probability of state reconfiguration. 14.The method of 13 wherein energy accepted by a receiving regularity isassociated with a stabilizing feedback to volatile links of said sendingregularity.
 15. A system for the self-organized growth of at least onelogic pathway, said system comprising: a plurality of cores capable ofbeing communicated via a packet routing architecture, wherein at leastone core includes sub-modules that interact dynamically with oneanother; a link formed between a regularity within said at least onecore and at least one other core via a link-flow-selection process; andtransmission means for transmitting a digital data packet between saidat least one core and said at least one other core to communicate anactivation of said regularity and to exchange energy to thereby growsaid at least one logic pathway in a self-organized manner an inputpacket receive module wherein at least one input packet received viasaid input packet receive module; transmitting said at least one packetto a thermodynamic content addressable memory module; mapping a senderaddress to a dedicated input line on a pattern register; performing abit-matching between said sender address and an internally stored bitpattern; and overwriting an existing entry such that aleast-energy-dissipating link is over-written first when a new inputaddress is present.
 16. The system of claim 15 wherein said plurality ofhardware cores is capable of representing said at least one core. 17.The system of claim 15 wherein said sub-modules interact to evolve saidat least one logic pathway.
 18. The system of claim 15 furthercomprising a flow network created between a senor input and a sinkevent.
 19. The system of claim 18 wherein said sink event comprises aprediction of said sensor input.
 20. The system of claim 15 wherein:said sub-modules interact to evolve said at least one logic pathway; anda flow network created between a senor input and a sink event.